WO2024052554A1 - Jumping mat arrangement - Google Patents

Abstract

The invention relates to a jumping mat arrangement for a trampoline, with a sensor arrangement (11), which comprises first sensor lines (12) and second sensor lines (13), wherein the first sensor lines and the second sensor lines form crossing points (14) and wherein the first sensor lines (12) and the second sensor lines (13) are insulated from one another at least in the region of the crossing points (14). Using the jumping mat arrangement according to the invention, the position of the user of the trampoline can be precisely resolved.

Description

Jumping mat arrangement

Description

The invention relates to a jumping mat arrangement for a trampoline, with a jumping mat that has an upper side and a lower side, and with a sensor arrangement for recording information when the jumping mat is used.

The invention is directed to any type of trampoline such as fitness trampolines or garden trampolines. Such trampolines have a surrounding frame and a jumping mat that is stretched within the frame via spring elements. The spring elements are, for example, metallic spiral springs or rubber-elastic cable sections, in particular cable rings. The jumping mat is designed to be flexible and allows the user to swing or jump gently on the top of the jumping mat. The surrounding frame is, for example, over Legs held at a distance from the ground, which are attached to the frame.

Such trampolines are known and have proven themselves. However, in the prior art there was a need to obtain additional information about the use of the trampoline.

A jump counter is known from practice that counts the number of jumps made. For example, a contact sensor with a conductive metal ball is used, which generates an electronic edge through contact with each jump. Each edge corresponds to a jump.

From EP 2 962 736 B1 a trampoline with sensors is known with which forces or accelerations acting on the jumping mat are detected. The sensors are located on the underside of the legs so that the trampoline rests completely on the sensors.

From EP 2 934 704 B1 a trampoline with acceleration sensors is known, which are arranged in pairs around the jumping mat. The sensors define a coordinate space. This allows the jumping zone of the jumping user of the trampoline to be determined.

The known sensor systems are inaccurate.

The invention is based on the object of creating a trampoline with a sensor arrangement that enables a higher spatial resolution.

This task is solved by a jumping mat arrangement with the features of patent claim 1. According to the invention, the sensor arrangement comprises first sensor lines and second sensor lines, with the first sensor lines and the second sensor lines forming crossing points. The first and second sensor lines preferably extend over the jumping mat. The crossing points allow a high resolution of the sensor arrangement. This makes it possible to determine exactly where the user is on the jumping mat. The first and second sensor lines expediently form a matrix that covers a jumping area of the jumping mat, whereby edge areas of the jumping mat can be left out.

The latter are rarely jumped on and are sometimes used to hang the jumping mat on the frame of the trampoline.

The first sensor lines and the second sensor lines are insulated from one another at least in the area of the crossing points. In this area there is no electronic contact between the sensor lines. The crossing points can be individually isolated. It is simpler if several crossing points are isolated by a common insulator, which can be flat, in particular layer-like, as will be explained in more detail below.

The invention creates completely new possible applications. Through digital imaging when using the trampoline, it is possible, for example, to specify and control movement sequences (e.g. foot positions or jumping frequencies). This enables individual training on the trampoline. There are also a variety of play options. Finally, digitalization also allows for one Networking of several trampolines, which creates opportunities for interaction.

The sensor arrangement is preferably a capacitive sensor arrangement. The first sensor lines advantageously form transmission lines and the second sensor lines form reception lines or vice versa. The first and second sensor lines are connected to an evaluation unit that has a controller. In addition, the evaluation unit can also include a connection field for connecting the sensor lines and/or a power supply. The controller will be arranged on a circuit board, for example. The connection field can also be arranged on the circuit board, in which case it is preferably provided that the controller is connected to the connection field via conductor tracks. Finally, the evaluation unit can also have an interface for an evaluation computer of the data supplied by the controller.

During a measurement process, field lines emanate from the transmitting line to the receiving line at fixed time intervals and are deflected when the foot (or another part of the body) approaches. The strength of the deflection is proportionally converted into a distance of the approached medium by the controller and software. This non-contact measuring principle is e.g. B. known from touch screens or capacitive proximity sensors.

When using the trampoline, the jumping mat is deformed. For this purpose, the jumping mat is designed to be flexible. When using the trampoline, the first and second sensor lines are deflected together with the jumping mat. The deflection can also contain an expansion component. In this In connection with this, it is proposed in a further development of the invention that the first and second sensor lines each run in a main extension direction, whereby they alternately jump laterally in the direction of the main extension direction. The sensor lines do not run linearly, but jump laterally, for example in a zigzag shape or meandering. On the one hand, the jumpring gives the sensor lines - and thus the entire sensor arrangement - improved flexibility. On the other hand, the sensor area also increases. This is particularly true if the sensor lines jump in the plane of the jumping mat or a plane parallel to the jumping mat, as is considered advantageous.

The jumping mat has a top and a bottom. The user of the trampoline jumps or swings on the top. The top side is therefore particularly stressed or claimed. An advantageous exemplary embodiment is characterized in that the first sensor lines and the second sensor lines run on the underside. This protects them from mechanical overstress. Such a sensor arrangement has a long service life.

An advantageous embodiment of the invention is characterized in that a flexible intermediate layer is arranged between the first sensor lines and the second sensor lines. The intermediate layer is a carrier layer for the sensor lines, which are preferably attached, in particular sewn, to the intermediate layer. The intermediate layer is advantageously electrically insulating. In this respect, it is considered advantageous if the intermediate layer extends over several, preferably over all intersection points. The intermediate layer thus fulfills two tasks, namely a carrier function and an insulating function.

It has already been mentioned above that the sensor lines are advantageously sewn onto the intermediate layer. They can also be attached directly to the jumping mat, in particular glued or sewn on. However, the intermediate layer offers the advantage of a simple manufacturing process and special protection for the sensor lines. This is particularly true if the intermediate layer is arranged on the underside of the jumping mat, as is considered advantageous.

If the sensor lines are sewn on, the sensor lines are expediently designed as conductive individual threads that can be sewn. Such conductive threads are known.

The intermediate layer is preferably designed to be flexible. This allows it to follow the deflection of the jumping mat.

In a preferred exemplary embodiment, the intermediate layer is designed to be elastic. For this purpose, the intermediate layer expediently has an elastane content. It is particularly advantageously biased towards the jumping mat. This is particularly true if the intermediate layer is firmly connected to the jumping mat (for example when sewn). But even if the intermediate layer and the jumping mat are releasably connected, the intermediate layer can be prestressed to reduce sag. Ideally, the intermediate layer is in the rest position of the jumping mat, in which the jumping mat is not is loaded, flat on the jumping mat, whereby in practice the intermediate layer will usually be at a certain distance from the jumping mat due to its own weight. This distance is kept as small as possible so that the jumping mat lies against the intermediate layer even with a slight deflection.

It was already mentioned above that it is advantageous for the sensor lines to jump. In this context, it has proven to be advantageous in terms of manufacturing technology that the first sensor lines and the second sensor lines are sewn onto the intermediate layer in a zigzag stitch.

The first sensor lines are advantageously applied to one side and the second sensor lines to the other side of the intermediate layer, in particular sewn on. If the sensor lines are sewn on, it is advisable to use a non-conductive thread as the lower thread. This ensures that the first and second sensor lines are isolated from each other.

The intermediate layer is preferably attached to the jumping mat. As a result, it is directly coupled to the jumping mat and moves with it when the trampoline is used. For example, the intermediate layer is sewn onto the jumping mat. Then there is a solid connection. Alternatively, the jumping mat and the intermediate layer are detachably connected to one another. For example, a Velcro connection or a connection using snap fasteners can be considered here. A detachable connection has the advantage that the intermediate layer can be replaced or retrofitted. The intermediate layer preferably consists of a textile material, but can also be made of other technical blended fabrics.

In an advantageous embodiment, the intermediate layer is connected to the jumping mat at least in the area of the circumference. Such attachment allows precise positioning of the intermediate layer in relation to the jumping mat. In a preferred exemplary embodiment, the intermediate layer is attached essentially exclusively in the area of the circumference. Essentially no fastening is then provided in the actual jumping area, whereby “essentially” in the present case means that the intermediate layer can be connected to the jumping mat at individual points in the jumping area in order to couple the intermediate layer to the jumping mat.

In the matrix resulting from the first and second sensor lines, a large-area and at the same time high-resolution coverage of the jump area is desirable. It has proven to be particularly advantageous that the first sensor lines and the second sensor lines each run curved in their main extension direction. Due to the curvature, the jumping surface can be advantageously covered if the jumping mat is round. The curvature does not necessarily have to correspond to the curvature or correspond to the radius of the jumping mat. Rather, it is sufficient for the sensor lines running on the outside if they are less curved than the edge of the jumping mat.

An advantageous embodiment is characterized in that the distance between adjacent crossing points in the radial direction of the jumping mat is a larger distance from the outside than inside. It is considered particularly advantageous if the curvature of the first and/or the second sensor lines becomes greater towards the edge of the jumping mat. Such a matrix creates a greater sensor density in the main jumping area of the jumping mat in order to increase the measurement accuracy there. In the circumferential area, a jumping mat is less likely to be jumped on/stressed, so a coarser sensor matrix is sufficient here.

As already mentioned at the beginning, the first and second sensor lines are connected to an evaluation unit. This means that the sensor lines advantageously converge in a connection field. For this purpose, it is advantageously proposed that the first sensor lines and/or the second sensor lines are guided in the edge region of the jumping mat arrangement along the circumference of the jumping mat arrangement to the evaluation unit. If an intermediate layer is used, the first and/or the second sensor lines are preferably routed to the evaluation unit in the edge region of the intermediate layer. Alternatively, they are guided to the evaluation unit in the edge area of the jumping mat (which is possible with or without an intermediate layer). In particular, it is considered advantageous if the first sensor lines are routed outside the second sensor lines to the evaluation unit or vice versa. It is also considered advantageous if the first sensor lines towards the evaluation unit are arranged at the top of the intermediate layer and the second sensor lines are arranged at the bottom or vice versa. This allows an alternating connection method, for example with a two-sided connection panel at the bottom and top. The connection field preferably has connections for connecting the first and second sensor lines. The connections are designed, for example, as push buttons that create a detachable connection between the controller and the sensor lines, which is considered advantageous. The connections can also be designed as plug connectors, which are advantageously also designed to be detachable. The detachable connection offers the possibility of detaching the evaluation unit from the jumping mat arrangement and, for example, repairing, replacing or retrofitting it. Alternatively, the sensor lines are firmly connected to the connection field, for example soldered. Such a construction is very compact.

When connecting the sensor cables to the connection field, care must be taken to ensure that the sensor cables are insulated in an area where they can come into contact with each other due to the movement of the jumping mat, so that the lowest possible crosstalk between neighboring sensor cables is ensured. For this purpose, the sensor cables are preferably coated with silicone to ensure mechanical protection and reduce crosstalk (NEXT).

The evaluation unit is advantageously attached to the jumping mat or the intermediate layer. It has proven to be particularly advantageous to arrange the evaluation unit in the peripheral area of the jumping mat arrangement, expediently in an edge of the jumping mat that extends over hooks of the jumping mat. If an intermediate layer is used, the evaluation unit is preferably accommodated in an edge that lies radially outside of the attachment of the intermediate layer to the jumping mat. An advantageous embodiment of the invention is characterized in that the first sensor lines each form first electrodes and the second sensor lines each form second electrodes, that the first electrodes and the second electrodes are insulated from one another in the area of the crossing points by insulation, and that the first electrodes and the second electrodes together with the insulation in the area of the crossing points each form a sensor. Each sensor is therefore formed by a first electrode, the insulation and a second electrode. The sensor is preferably a capacitive sensor. The first and second sensor lines advantageously create a grid of individual sensors at the crossing points. As already stated above, the crossing points can be individually isolated by the insulation. It is simpler if several crossing points are isolated by a common insulation, which can be flat, in particular layer-like.

The invention is explained in more detail below using a preferred exemplary embodiment in connection with the attached drawing. The drawing shows in:

Figure 1 is a schematic representation of a perspective view of a trampoline according to the invention;

Figure 2 is a schematic representation of a view of the trampoline according to Figure 1 from below;

Figure 3 is a schematic representation of a sensor arrangement according to the invention of the trampoline according to Figure 1 alone; Figure 4 is a schematic representation of an enlargement of detail D from Figure 2; and

Figure 5 is a schematic representation of a sectional view of a section of the trampoline according to Figure 1.

Figure 1 shows a trampoline according to the invention with a surrounding frame 1, from which legs 2 extend, which preferably run vertically when the trampoline is set up. Other legs or leg arrangements are also possible. A jumping mat 3 is stretched in the frame 1 via rope rings 4 which are hooked into hooks 5 and wound around the frame 1 . The hooks 5 are attached to the jumping mat 3, for example sewn. Such a basic structure is known from the prior art. Alternative fastening options are also known. For example, the jumping mat 3 can be connected to the frame by means of elastic open rope sections, which are also suspended in hooks. Suspension using spiral springs is also known. The invention is independent of the type of suspension.

The jumping mat 3 is designed to be flexible. When subjected to stress, it deforms accordingly. The restoring forces for tensioning the jumping mat 3 are essentially provided by the rope rings 4.

The jumping mat 3 has an edge 6 which is designed all around and preferably extends over the hooks 5 . The edge 6 is advantageously designed to be padded. If the user of the trampoline comes off the jumping surface and steps on the edge 6, contact will occur (for example when jumping). The edge 6 expediently runs outside the jump area stretched by the hooks 5.

The reference symbol 7 denotes a holding rod, which can be connected to the frame 1 via a receptacle 8. Using the handrail 7, certain exercises on the trampoline can be carried out more easily by the user of the trampoline holding on to the handrail. A display 9 is arranged at the top of the support rod 7 and can be used to read user parameters such as the vibration amplitude or the user's position. For this purpose, the display 9 is connected via a cable 10 to an evaluation unit, which will be described in more detail below. The display 9 can also be designed as an input unit through which parameters can be entered, such as a desired sequence of jumps.

Figure 2 shows a view of the trampoline according to Figure 1 from below. From this view, a sensor arrangement 11 can be clearly seen, which is arranged below the jumping mat 3 and is used to record information when using the jumping mat 3. For example, the sensor arrangement 11 is connected to the jumping mat 3. It is considered particularly advantageous if the sensor arrangement 11 is detachably connected to the jumping mat 3. It can then be retrofitted or only used when required. For example, the sensor arrangement 11 is connected to the jumping mat 3 via a Velcro connection. Alternatively, press buttons can be considered. For a functional attachment, it is sufficient if the sensor arrangement 11 is only connected to the jumping mat 3 at individual points or areas. The sensor arrangement 11 has first sensor lines 12 and second sensor lines 13 which form crossing points 14 . For reasons of clarity, only some intersection points 14 in FIG. 2 are provided with reference symbols.

The sensor lines 12, 13 are connected to an evaluation unit 15 and are each designed as transmitting and receiving lines. It is irrelevant whether the sensor cables

12 receiving lines and the sensor lines are 13 transmitting lines or vice versa. It is important that the sensor lines 12 and the sensor lines 13 are electrically insulated from one another in the area of the crossing points 14 . In the area of the crossing points 14, the sensor arrangement 11 forms capacitive measuring points that can detect and localize the position of a person.

The insulation can be realized, for example, by individual insulation of the sensor lines 12, 13 in the area of the crossing points 14. Each crossing point 14 is therefore individually isolated. In terms of manufacturing technology, it is advantageous to insulate the sensor lines 12, 13 over a larger area, for example over several crossing points 14. In the present case, the insulation is provided by an intermediate layer 16, as will be explained in more detail in connection with FIG. 3.

The first and second sensor lines 12 , 13 are sewn onto the intermediate layer 16 . So that the sensor lines 12, 13 do not touch each other, the first sensor lines 12 are advantageously sewn on one side of the intermediate layer 16 and the second sensor lines 13 on the other side. This is why the second sensor lines are

13 shown in dashed lines in Figure 2. They lie on the other side of the intermediate layer, which advantageously faces the jumping mat 3.

The intermediate layer 16 is preferably connected to the jumping mat 3, for example sewn. As already mentioned before, a detachable connection can also be provided, as will be described in more detail in connection with Figure 3.

The first sensor lines 12 and the second sensor lines 13 therefore run below the jumping mat 3 - with a trampoline in the use position. This protects the sensor lines 12, 13.

In the advantageous exemplary embodiment of the trampoline according to the invention shown, the first sensor lines 12 and the second sensor lines 13 each run curved in their main direction of extension. This has the advantage that the sensor lines 12 , 13 can also cover the edge areas of the jumping mat 3 particularly well. The main direction of extension is the direction in which the respective sensor line mainly extends. Lateral offsets, which will be discussed in more detail below, do not influence the main direction of extension.

It is considered particularly advantageous that the distance between adjacent crossing points 14 in the radial direction of the jumping mat 3 is larger on the outside than on the inside. The measurement density is therefore denser in the center of the jumping mat 3 than outside, since the user's contact with the jumping mat typically takes place in the center. In this context, it is considered advantageous if the first sensor lines 12 and/or the second sensor lines 13 extend radially outward towards the free end of the jumping mat 3 or the intermediate layer 16 have a greater curvature than the respective sensor lines 12, 13 located more in the center of the jumping mat 3 or the intermediate layer 16.

The intermediate layer 16 has an edge 17 which is preferably designed to be circumferential. The edge 17 is advantageously located outside the attachment of the intermediate layer 16 to the jumping mat 3. The first sensor lines 12 and the second sensor lines 13 are preferably routed to the evaluation unit 15 in the area of the edge 17. In the area of the edge 17, the first sensor lines 12 and the second sensor lines 13 expediently converge towards one another. This is advantageous in terms of space.

Figure 3 shows the sensor arrangement 11 alone. The intermediate layer 16 is folded over on one side so that the second sensor lines 13 running on the top are also visible. It was already noted above that the sensor arrangement 11 can advantageously be detachably connected to the jumping mat 3 . This allows retrofitting or attachment only when necessary. For this purpose, the intermediate layer 16 has a Velcro connection 18, which in the present case is designed in several parts. The connection to the jumping mat 3 only takes place in individual places. The Velcro connection is only indicated as an example in FIG. It can also be arranged radially further inwards or, for example, have a different shape. It is also possible to design it as a circumferential Velcro connection ring.

As already stated previously, the sensor lines 12 , 13 are sewn onto the intermediate layer 16 . The intermediate layer 16 experiences the same when the jumping mat 3 is deflected a deflection. The intermediate layer 16 must therefore be highly flexible and preferably also elastic. In this context, it has proven to be particularly advantageous if the first sensor lines 12 and the second sensor lines 13 project laterally to their main direction of extension. This allows the intermediate layer 16 to be stretched without the risk of the sensor lines 12, 13 tearing.

Figure 4 shows detail D from Figure 2. This makes it clear that the lateral jumps can be particularly advantageously realized using a zigzag stitch. Such a zigzag stitch is also advantageous in that it increases the sensor area.

Figure 5 shows an abstract representation of a sectional view through the edge region of the jumping mat 3 and the sensor arrangement 11. The jumping mat 3 is tensioned within the surrounding frame 1 by means of the hooks 5 and the rope rings 4. The edge 6 extends over the hooks 5 and offers the user protection if he does not hit the actual jumping surface. This is particularly true if the edge 6 is padded, as is considered advantageous.

The jumping mat 3 has a top 19 and a bottom 20. The top 19 is at the top when the trampoline is in use. The intermediate layer 16 is attached to the underside 20 of the jumping mat 3. The edge 17 of the intermediate layer 16 extends analogously to the edge 6 under the hooks 5. The edge 17 is advantageously also padded. The evaluation unit 15 is accommodated in the edge 17. The padding protects the evaluation unit 15 against possible shock loads, for example in the event of a misstep by the user.

Reference symbol list

Frame

leg

Jumping mat

Rope ring

Hook

edge

Grab bar

Recording

display

Cable

Sensor arrangement first sensor line second sensor line

crossing point

Evaluation unit

Interlayer

edge

Velcro connection

Top

bottom

Claims

Jumping mat arrangement

Pa t ent spri 1 c h e jumping mat arrangement for a trampoline, with

- a jumping mat (3) which has a top (19) and a bottom (20), and with

- a sensor arrangement (11) for recording information when using the jumping mat (3), characterized in that

- That the sensor arrangement (11) has first sensor lines

(12) and second sensor lines (13), the first sensor lines and the second sensor lines forming crossing points (14), and

- That the first sensor lines (12) and the second sensor lines (13) are insulated from one another at least in the area of the crossing points (14).

Jumping mat arrangement according to claim 1, characterized in that the first sensor lines (12) and the second sensor lines (13) each run in a main extension direction, whereby they alternately jump laterally in the direction of the main extension direction. Jumping mat arrangement according to claim 1 or 2, characterized in that the first sensor lines (12) and the second sensor lines (13) run on the underside (20) of the jumping mat (3). Jumping mat arrangement according to one of claims 1 to 3, characterized in that a flexible intermediate layer (16) is arranged between the first sensor lines (12) and the second sensor lines (13), which extends over several, preferably over all, crossing points (14). . Jumping mat arrangement according to claim 4, characterized in that the first sensor lines (12) and the second sensor lines (13) are sewn onto the intermediate layer (16). Jumping mat arrangement according to claim 5, characterized in that the first sensor lines (12) and the second sensor lines (13) are sewn onto the intermediate layer (16) in a zigzag stitch. Jumping mat arrangement according to one of claims 4 to 6, characterized in that the first sensor lines (12) are arranged on one side and the second sensor lines (13) on the other side of the intermediate layer (16). 8. Jumping mat arrangement according to one of claims 4 to 7, characterized in that the intermediate layer (16) is attached to the jumping mat (3).

9. Jumping mat arrangement according to one of claims 4 to 8, characterized in that the intermediate layer (16) is connected to the jumping mat (3) at least in the area of the circumference.

10. Jumping mat arrangement according to one of claims 1 to 9, characterized in that the first sensor lines (12) and the second sensor lines (13) are each curved in their main direction of extension.

11. Jumping mat arrangement according to one of claims 1 to 10, characterized in that the distance between adjacent crossing points (14) seen in the radial direction of the jumping mat (3) is larger on the outside than on the inside.

12. Jumping mat arrangement according to one of claims 1 to 11, characterized in that the first sensor lines (12) and / or the second sensor lines (13) are guided in an edge region of the jumping mat arrangement along the circumference of the jumping mat arrangement to an evaluation unit (15).

13. Jumping mat arrangement according to one of claims 1 to 12, characterized in that the first sensor lines (12) each form first electrodes and the second sensor lines (13) each form second electrodes, that the first electrodes and the second electrodes in the area of the crossing points (14 ) are insulated from each other by insulation, and that the first electrodes and the second electrodes together with the insulation in the area of the crossing points (14) each form a preferably capacitive sensor. 14. Trampoline with a jumping mat arrangement according to one of claims 1 to 13.